Determining a Remaining Amount of Material in a Material Package

ABSTRACT

It may be determined that a material package has been used by determining that the material package has moved from a previously recorded location based upon location data corresponding to the material package and a beacon code. The location data may correspond to the material package and the beacon code being periodically reported by a beacon located proximate to the material package. Next, a weight of the material package that has been used subsequent to the material package being used may be received and, based upon the beacon code and in response to receiving the weight of the material package; the material database for a material package record may be queried. A remaining amount of material corresponding to the material package may be calculated based upon the received weight and data from the material package record found from the material package record.

RELATED APPLICATIONS

This application is a Continuation-in-part of U.S. application Ser. No.15/188,012 entitled “Determining a Remaining Amount of Material in aMaterial Package,” filed Jun. 21, 2016, which is incorporated herein byreference, which claims the benefit under provisions of 35 U.S.C.§119(e) of U.S. Provisional Application No. 62/302,925 filed Mar. 3,2016, U.S. Provisional Application No. 62/261,338 filed Dec. 1, 2015,and U.S. Provisional Application No. 62/182,709 filed Jun. 22, 2015,which are also incorporated herein by reference.

BACKGROUND

Just-in-time (JIT) manufacturing, also known as just-in-time production,is a methodology aimed primarily at reducing flow times withinproduction as well as response times from suppliers and to customers.JITR manufacturing may use radio-frequency identification (RFID). RFIDis the wireless use of electromagnetic fields to transfer data, for thepurposes of automatically identifying and tracking tags attached toobjects. The RFID tag can be affixed to an object and used to track andmanage inventory, assets, people, etc. For example, it can be affixed tocars, computer equipment, books, mobile phones, etc.

RFID provides a way for organizations to identify and manage tools andequipment (asset tracking), without manual data entry. RFID is beingadopted for item level tagging in retail stores. This provideselectronic article surveillance (EAS) and a self-checkout process forconsumers. Automatic identification with RFID can be used for inventorysystems. Manufactured products such as automobiles or garments can betracked through the factory and through shipping to the customer.

BRIEF DESCRIPTION OF THE FIGURES

The accompanying drawings, which are incorporated in and constitute apart of this disclosure, illustrate various embodiments of the presentdisclosure. In the drawings:

FIG. 1 is a block diagram of an operating environment for determining aremaining amount of material in a material package in accordance with atleast one example embodiment;

FIG. 2A shows a material package in accordance with at least one exampleembodiment;

FIG. 2B shows a material package in accordance with at least one exampleembodiment;

FIG. 2C shows a beacon in accordance with at least one exampleembodiment;

FIG. 3 is a flow chart of a method for determining a remaining amount ofmaterial in a material package in accordance with at least one exampleembodiment;

FIG. 4 is a flow chart of a method for providing moisture content of amaterial package in accordance with at least one example embodiment;

FIG. 5 is a block diagram of a computing device in accordance with atleast one example embodiment; and

FIG. 6 is a flow chart of a method for determining a remaining amount ofmaterial in a material package in accordance with at least one exampleembodiment.

DETAILED DESCRIPTION Overview

Determining a remaining amount of material in a material package may beprovided. First, it may be determined that the material package has beenused by determining that the material package has moved from apreviously recorded location based upon location data corresponding tothe material package and a beacon code. The location data may correspondto the material package and the beacon code being periodically reportedby a beacon located proximate to the material package. Next, a weight ofthe material package that has been used subsequent to the materialpackage being used may be received and, based upon the beacon code andin response to receiving the weight of the material package; thematerial database for a material package record may be queried. Aremaining amount of material corresponding to the material package maybe calculated based upon the received weight and data from the materialpackage record found from the material package record query.

Both the foregoing overview and the following example embodiment areexamples and explanatory only, and should not be considered to restrictthe disclosure's scope, as described and claimed. Further, featuresand/or variations may be provided in addition to those set forth herein.For example, embodiments of the disclosure may be directed to variousfeature combinations and sub-combinations described in the exampleembodiment.

Example Embodiments

The following detailed description refers to the accompanying drawings.Wherever possible, the same reference numbers are used in the drawingsand the following description to refer to the same or similar elements.While embodiments of the disclosure may be described, modifications,adaptations, and other implementations are possible. For example,substitutions, additions, or modifications may be made to the elementsillustrated in the drawings, and the methods described herein may bemodified by substituting, reordering, or adding stages to the disclosedmethods. Accordingly, the following detailed description does not limitthe disclosure. Instead, the proper scope of the disclosure is definedby the appended claims.

Consistent with embodiments of the disclosure, beacons may be applied tomaterial packages (e.g., wire reels) at a manufacture's staging area.Barcode scanner may then read and associate reel tags from the wirereels and the applied beacons from the wire reels. Data may be writtento the beacons' memory and a cloud database. Reel-less package beaconsmay be zip tied onto an inside tail of the wire or cable for example.Wooden reels may have beacons placed inside one of the holes predrilledinto the reel's inner drum. A scanner may be used to scan a reel tagbarcode and read the beacon barcode. As an alternative, an RFID (e.g.,an active RFID) chip on the beacon may be scanned with a barcode-UHFreader.

From the manufacture's staging area, material packages may be unloadedat a utility's location (e.g., an operations area) and may beautomatically logged into the cloud database with the new location. Thematerial packages may be read by a Wi-Fi network that may cover theentire operations area. Updated location and automated receipt ofmaterial data may be sent to the cloud database.

As material packages leave and return to the operations area on servicetrucks, UHF antennae scanners may read the beacon to log the events. TheWi-Fi network may provide duplicate reads. Material packages may beweighed after return and remaining footage of material on the materialpackages may be automatically calculated. As will be described below,moisture content of the material packages may be considered when theremaining amount of material on the material packages is determined.This may be (but not limited to) the case when, for example, woodenreels are used as the material package. To obtain the weight, thematerial packages may be placed on outdoor scales with a forklift. TheUHF antenna may read the beacon on the scale. A new footage may becalculated and written to both the beacon and the cloud database.Partial packages may be returned to the operations area for future use.Partial packages may be visible on the system through software on theserver for day-to-day, outage, or storm response situations.

FIG. 1 is a block diagram of an operating environment 100 in accordancewith embodiments of the disclosure. As shown in FIG. 1, operatingenvironment 100 may comprise a server 105, a network 110, a staging area115, and an operations area 120. Staging area 115 may include stagingdevice 125. Operations area 120 area may include operations device 130and interface 135. As will be described in greater detail below, stagingarea 115 may comprise a location where a material package may be stagedfor deliver to operations area 120.

FIG. 2A shows an example of a material package consistent withembodiments of the disclosure. As shown in FIG. 2A, the material packagemay comprise a wire reel 205 on which material may we wound. Wire reel205 may be made of wood, metal, or any other material. The material onwire reel 205, for example, may comprise electrical cable, electricalwire, flexible conduit, or any other material capable of being wound onwire reel 205.

FIG. 2B shows an example of a material package consistent withembodiments of the disclosure. As shown in FIG. 2B, the material packagemay comprise a wire coil 210 in which the material may be wound. No reelmay be present with wire coil 210. A wrapping material may be placedaround wire coil 210. The material in wire coil 210, for example, maycomprise electrical cable, electrical wire, flexible conduit, or anyother material capable of being wound in wire coil 210.

A package label 215 may be placed on the material package (e.g., wirereel 205 or wire coil 210). Package label 215, for example, may includean optical machine-readable representation of data relating to thematerial package to which it is attached. The optical machine-readablerepresentation may be readable by staging device 125. The opticalmachine-readable representation may comprise, but is not limited to, aone-dimensional (1D) bar code or a two-dimensional (2D) bar code. Forexample, package label 215 may comprise a material package code (i.e.,optical machine-readable representation) that may either contain: i)material package data corresponding to the material; or ii) an indexreferencing the material package data corresponding to the materialstored, for example, on server 105 or staging device 125.

The material package data may comprise, but is not limited to, a perunit weight of the material on the material package, weight of thematerial package prior to the material being placed on the materialpackage, moisture content of the material package at a particular time(e.g., the time it was weighed prior to the material being placed on thematerial package), a “dry” weight of the material package prior to thematerial being placed on the material package, a manufacture date forthe material, identification of a machine on which the material wasmade, an identification of an operator who operated the machine on whichthe material was made, identification of a machine on which the materialwas assembled and when, an identification of an operator who operatedthe machine on which the material was assembled and when, anidentification of what plant made each component of the material, anidentification of what plant that assembled the material, what lotnumber of raw material was used for the material, quality assurance andconformance data for all materials used to make the product, and how thematerial package was shipped.

The moisture content of the material package at the time it was weighedmay comprise a percentage of the material package weight prior to thematerial being placed on the material package due to moisture in thematerial package. For example, the material package prior to thematerial being placed on the material package may be 120 lbs. and themoisture content (when this weight was taken) may be measured at 20%. Inthis case, the “dry” weight of the material package prior to thematerial being placed on the material package may comprise 100 lbs.(i.e., 100 lbs.=120 lbs./(1+0.20)). Similarly, the amount of moisture inthe material package prior to the material being placed on the materialpackage may be 20 lbs. (i.e., 20 lbs.=120 lbs.−100 lbs.).

As stated above, the material package data may comprise a per unitweight of the material on the material package. Consistent withembodiments of the disclosure, the per unit weight of the material maybe a standard value that may be used and accepted as the per unit weightof the material. For example, the material may comprise an electricalcable comprising 1/0 ACSR Raven. A manufacturer of 1/0 ACSR Raven maypublish that the per unit weight of such a cable is 0.145 lbs. per foot.Consequently, 0.145 lbs. per foot may be used in the material packagedata as the per unit weight of the material on the material packageanytime the material comprises 1/0 ACSR Raven. As another example, amanufacturer of underground 4/0 Secondary Triplex Sweatbriar may publishthat the per unit weight of such a cable is 0.709 lbs. per foot.Consequently, 0.709 lbs. per foot may be used in the material packagedata as the per unit weight of the material on the material packageanytime the material comprises 4/0 Secondary Triplex Sweatbriar.

Consistent with other embodiments of the disclosure, the per unit weightof the material may be calculated on a package-by-package basis. Forexample, the manufacturer may know the weight of the material packageprior to the material being placed on the material package. Also, themanufacturer may measure the amount of material that is being placed onthe material package. In the case of a cable, the measured amount may bethe length of the cable being placed on the material package. After thematerial is placed on the material package, the material package may beweighed, for example, at staging area 115, to obtain a weigh of thematerial package after the material is placed on the material package.The weight of the material placed on the material package may becalculated by subtracting the weight of the material package prior tothe material being placed on the material package from the weight of thematerial package after the material is placed on the material package.The weight of the material placed on the package may be divided by theamount of material placed on the package to calculate a per unit weightof the material placed on the package. This may be done on apackage-by-package basis.

For example, a material for a package my comprise 1/0 ACSR Raven. Theweight of the material package prior to the material being placed on thematerial package may comprise 200.00 lbs. and the amount of materialplaced on the package may be 998.1 feet. After the amount of material isplaced on the material package, the manufacturer may determine that theweight of the material package is 343.71 lbs. The weight of the materialplaced on the material package may be calculated by subtracting theweight of the material package prior to the material being placed on thematerial package (i.e., 200.00 lbs.) from the weight of the materialpackage after the material is placed on the material package (i.e.,343.71 lbs.). In this example, the weight of the material placed on thematerial package may comprise 143.71 lbs. (i.e., 343.71 lbs.−200.00lbs.). The weight of the material placed on the package may be dividedby the amount of material placed on the package to calculate a per unitweight of the material placed on the package. In this example, the perunit weight of the material placed on the package may comprise 0.144lbs. per foot (i.e., 143.71 lbs. divided by 998.1 feet). Thispackage-by-package calculated per unit weight of the material may beused in the material package data that may go along with its respectivepackage.

The material contained in the material package may comprise any type ofmaterial. For example, the material may comprise a continuous and/orhomogeneous substance of which a portion may be taken from the materialpackage and consumed. When a portion of the material is taken from thematerial package, the material remaining in the material package maystill be the same; it's just that less of the material may remain in thematerial package when some of the material is removed from the materialpackage. The material may comprise a longitudinally continuous substancethat may be consumed by its length, for example, cable, wire, conduit,and the like. In other words, the material may comprise one long,continuous, flexible piece that may be wound in a coil or on a reel andthen partially consumed by its length by cutting off a longitudinalportion of the material. The material may comprise a homogeneoussubstance, for example, a gas, liquid, solid (e.g., granular) substancefor which the material package may comprise a tank or any other suitablecontainer.

FIG. 2C shows a beacon 220. For example, beacon 220 may be placedanywhere on the inside or outside of wire reel 205 or wire coil 210.Regarding wire coil 210, beacon 220 may be attached (e.g., via zip tied)to the tail end of the material (e.g., wire or cable) in the coil ofwire comprising wire coil 210. Beacon 220 may include a beacon labelthat may comprise an optical machine-readable representation of a beaconcode unique to beacon 220.

Beacon 220 may also include a memory that may be read from wirelesslyand written to wirelessly. For example, the aforementioned materialpackage code may be written to beacon 220's memory. Furthermore, theinitial amount of material in material package may be written to beacon220's memory. As material is consumed from the material package, theremaining amount of material may be written to beacon 220's memory.

Beacon 220 may make wireless transmissions that may include its uniquebeacon code. Beacon 220 may also utilize the Global Positioning System(GPS) to obtain data indicating beacon 220's location and may includethis data indicating beacon 220's location in the wirelesstransmissions. Beacon 220 may obtain its location data periodically orwhen it is pinged (e.g., by staging device 125 or operations device130). Beacon 220 may store its location data in its memory. Thesetransmissions may also include data corresponding to some or all ofbeacon 220's memory. Beacon 220 may make these wireless transmissionsperiodically or in response to being pinged (e.g., by staging device 125or operations device 130). Beacon 220's transmissions may be encoded.Beacon 220, for example, may use active RFID or Bluetooth.Notwithstanding, wireless communications to and from beacon 220 maycomprise any form of wireless communications including, but not limitedto, Wi-Fi, Bluetooth, and RF. Beacon 220 may be placed on the materialpackage.

FIG. 3 is a flow chart setting forth the general stages involved in amethod 300 consistent with an embodiment of the disclosure fordetermining a remaining amount of material in a material package. Method300 may be implemented using, for example, server 105, staging device125, and operations device 130, each of which may be embodied incomputing device 500 as described in more detail below with respect toFIG. 5. Ways to implement the stages of method 300 will be described ingreater detail below.

Method 300 may begin at starting block 305 and proceed to stage 310where server 105 may receive a material package code corresponding to amaterial package comprising material. For example, the material package(e.g., wire reel 205 or wire coil 210) may be manufactured by amanufacturer and placed in staging area 115 for shipment to operationsarea 120 maintained by a purchaser of the material package for example.The purchaser may comprise, but is not limited to, a utility company orcontractor who may wish to consume the material.

An operator for the manufacture my use staging device 125 to obtain thematerial package code from the material package and transmit thematerial package code to server 105 over network 110. For example,staging device 125 may comprise a scanner capable of reading packagelabel 215. The operator may use the scanner to read package label 215 toobtain the material package code and then transmit the material packagecode to sever 105. Package label 215 may be placed on the materialpackage at any point during the manufacturing process. Server 105 mayaccordingly receive the material package code from the scanner operatedby the operator.

From stage 310, where server 105 receives the material package codecorresponding to the material package comprising the material, method300 may advance to stage 315 where server 105 may receive a beacon codecorresponding to a beacon associated with the material package. Forexample, beacon 220 may have been placed on the material package (e.g.,wire reel 205 or wire coil 210). Beacon 220 may be placed on thematerial package at any point during the manufacturing process. Thematerial database and the memory in beacon 220 may be updated when thematerial package is filled. Beacon 220 may include beacon label 225 thatmay comprise an optical machine-readable representation of the beaconcode unique to beacon 220. Beacon 220 may also make wirelesstransmissions that may include its unique beacon code. The operator mayuse the scanner to read beacon label 225 or to receive the wirelesstransmission from beacon 220 to obtain the beacon code. The operator mayuse the scanner to then transmit the beacon code to sever 105. Server105 may accordingly receive the beacon code from the scanner operated bythe operator.

Once server 105 receives the beacon code corresponding to the beaconassociated with the material package in stage 315, method 300 maycontinue to stage 320 where server 105 may record the beacon code in amaterial package record corresponding to the received material packagecode. The material package record may include the material package datacorresponding to the material. The material package record may be in amaterial database. For example, the material package code may eithercontain: i) the material package data corresponding to the material; orii) an index referencing the material package data corresponding to thematerial stored, for example, on server 105. If the material packagecode contains an index referencing the material package datacorresponding to the material stored, for example, on server 105, thenserver 105 may look up the material package data corresponding to thereceived material package code. Now having both the beacon code and thematerial package data corresponding to the material on the materialpackage, server 105 may create and record the beacon code in a materialpackage record corresponding to the received material package code. Thematerial package record for the material package may include: i) thebeacon code for the beacon on the material package; and ii) the materialpackage data corresponding to the material on the material package.

After server 105 records the beacon code in stage 320, method 300 mayproceed to stage 325 where server 105 may update location data in thematerial package record when the material package enters operations area120 for the first time. For example, the material package (e.g., wirereel 205 or wire coil 210) may be shipped from staging area 115 tooperations area 120. Operations area 120 may be maintained by thepurchaser of the material package. As the material package entersoperations area 120, interface 135 may read beacon 220 for its beaconcode. Interface 135 may transmit the beacon code to operations device130. In turn, operations device 130 may report the read beacon code toserver 105. In response, server 105 may update location data in thematerial package record. The updated location data may indicate that thematerial package is now located in operations area 120 and is no longerin staging area 115.

From stage 325, where server 105 updates the location data in thematerial package record, method 300 may advance to stage 330 whereserver 105 may receive the beacon code in response to the egress of thematerial package from operations area 120. For example, a crew workingfor the operator of operations area 120 may have a need for materiallocated on the material package to perform a certain job. As a result,the crew may load the material package on a vehicle and drive thevehicle from operations area 120 in order to go and perform the job. Asthe material package leaves operations area 120, interface 135 may readthe beacon code from beacon 220 located on the material package. Inresponse, interface 135 may report this reading of the beacon code frombeacon 220 to operations device 130 that may in turn report this toserver 105. Consequently, server 105 (and operations device 130) may logthe egress of the material package from operations area 120.

Once server 105 receives the beacon code in response to the egress ofthe material package in stage 330, method 300 may continue to stage 335where server 105 may receive the beacon code in response to the ingressof the material package back into operations area 120. For example, thecrew working for the operator of operations area 120 may have performedthe job that needed the material from the material package. As a resultof the completion of the job, the crew may return to operations area 120with the material package. During the job, the crew may have taken aportion of the material from the material package in order to completethe job. As the material package reenters operations area 120, interface135 may read the beacon code from beacon 220 located on the materialpackage. In response, interface 135 may report this reading of thebeacon code from beacon 220 to operations device 130 that may in turnreport this to server 105. Consequently, server 105 (and operationsdevice 130) may log the ingress of the material package back intooperations area 120.

After server 105 receives the beacon code in response to the ingress ofthe material package in stage 335, method 300 may proceed to stage 340where server 105 may receive a weight of the material package inresponse to the ingress of the material package back into the operationsarea. For example, because the material package is reentering operationsarea 120, a portion of the material may have been removed from thematerial package. Because the portion of the material may have beenremoved from the material package, it is desirable to know how muchmaterial remains on the material package. In order to determine how muchmaterial remains on the material package, a weight of the returnedmaterial package may be obtained and used to calculate the remainingmaterial as described below. Another way to determine how much materialremains on the material package may be for the crew to determine howmuch material they removed from the material package. The crew may use amobile device to read the beacon code and send a value of the amount ofmaterial used to server 105 where the material package record may beupdated based on the material used and the read beacon code.

The weight of the returned material package may be obtained in any way.For example, upon ingress of the material package back into operationsarea 120, the material package may be placed in a holding area forweighing. Once the material package has been weighed, the weight may bereported to operations device 130 that may in turn report the weight ofthe material package to server 105.

In addition to the weight of the material package, the moisture contentof the returned material package may also be obtained and reported toserver 105. For example, when the material package comprises a reel(e.g., a wooden reel), a moisture device (e.g., a moisture meter) may beused to obtain the moisture content of the reel. The moisture meter maycomprise, but is not limited to, an L600 Series Digital RecordingHandheld Moisture Meter provided by Wagner Meters of 326 Pine GroveRoad, Rogue River, Oreg. 97537.

The moisture content of the reel may comprise a percent moisture value.Because the amount of moisture in the material package may fluctuateover time, the weight of the material package may not only change due tomaterial being removed, but the weight of the material package may alsochange due to moisture being added or taken away from the materialpackage. The moisture device may read the percentage of moisture in thematerial package (e.g., reel). One moisture percentage reading may betaken or several moisture percentage readings may be taken at differentlocation on the material package and averaged.

Consistent with other embodiments of the disclosure, the moisturecontent value may be obtained in other ways. For example, a samplematerial (e.g., wood) being the same or similar to the material that thematerial package is made of may be kept in the same environment as thematerial packages in operations area 120. Rather than taking a moisturepercentage reading from each material package, the moisture percentagereading of the sample may be used. Furthermore, historic moisturecontent values for material (e.g., wood) being the same or similar tothe material that the material package is made of may be kept foroperations area 120's environment. Rather than taking a moisturepercentage reading of each material package, the moisture percentagehistoric values may be used instead. The historic values may be afunction of weather and season for example. Furthermore, the moisturecontent value may be obtained by method 400 described below. Once theweight and the moisture content value are obtained, the material packagemay be placed in the general warehouse of operations area 120 for use onyet another job.

Consistent with embodiments of the disclosure, equipment (e.g., a forktruck) used to remove the material package from the vehicle for thereturn of the material package back into operations area 120 may have adevice to weigh and read the moisture content of the material packageand wirelessly report the weight and moisture content to interface 135.Consistent with other embodiments of the disclosure, the materialpackage itself may include a device to weigh itself and report thisweight to interface 135. Furthermore, the material package itself mayinclude a device to obtain its own moisture content and report thisreading to interface 135.

From stage 340, where server 105 receives the weight and the moisturecontent value of the material package, method 300 may advance to stage345 where server 105 may query, based upon the beacon code received inresponse to the ingress of the material package back into operationsarea 120, the material database for the material package record. Forexample, server 105 may query the material database for the materialpackage record to obtain the per unit weight of the material on thematerial package, the previous weight of the material package before thejob, and the moisture content of the material package when the previousweight was taken of the material package before the job.

Once server 105 queries the material database in stage 345, method 300may continue to stage 350 where server 105 may calculate a remainingamount of material corresponding to the material package based upon thereceived weight and other data from the material package record foundfrom the material database query. For example, server 105 may subtractthe weight of the material package upon ingress from the previous weightof the material package and multiply this difference by the unit weightof the material to determine the amount of material used by the crew onthe job. For example, if the weight of the material package before thejob was 1,000 lbs., the weight of the material package after the job was900 lbs., and the per unit weight of the material was 1 lb./ft., thenthe amount of material used be the crew on the job would have been 100feet.

If the moisture content of the material package is to be considered,server 105, for example, may query the material database for thematerial package record to obtain: i) the per unit weight of thematerial on the material package; ii) the “dry” weight of the materialpackage prior to the material being placed on the material package; iii)the previous weight of the material package before the job; and iv) themoisture content of the material package at the time when the weight ofthe material package before the job was taken. These factors, alongwith: i) the weight of the material package after the job and ii) themoisture content of the material package at the time when the weight ofthe material package after the job was taken, may be used to determinethe amount of material used by the crew on the job when moisture contentof the material package is to be considered. Table 1 below shows anexample of the amount of material used by the crew on the job with themoisture content of the material package being considered. In thisexample, a value for the moisture weight is removed from the materialpackage weigh before and after the job and a more accurate amount ofmaterial used by the crew on the job may be determined because thefluctuation in the moisture content of the material package before andafter the job may be considered and removed.

TABLE 1 ″Dry″ % Moisture Material Per Unit Material Material whenweighed Moisture Package Wt. Weigh of Length Package wt. Package wt.before and Weight less moisture Material Used Lbs. Lbs. after job Lbs.Lbs. lbs./ft ft. Before job 1000 100 20% 20 980 After job  900 100 10%10 890 Weight of material used considering material package moisture  901 90 content.

After server 105 calculates the remaining amount of material in stage350, method 300 may proceed to stage 355 where server 105 may update thematerial package record in the material database with the calculatedremaining amount of material corresponding to the material package. Forexample, given the previous example of the consumption of 100 feet, ifthe material package record in the material database previouslyindicated that that the material package before the job was 1,000 ft.,server 105 may update the material package record in the materialdatabase with the calculated remaining amount of material comprising 900feet. As another example, given the previous example where moisturecontent of the material package was considered, the consumption was 90feet. If the material package record in the material database previouslyindicated that that the material package before the job was 1,000 ft.,server 105 may update the material package record in the materialdatabase with the calculated remaining amount of material comprising 910feet. Server 105 may also update the material package record in thematerial database with: i) the weight of the material package after thejob and ii) the moisture content of the material package at the timewhen the weight of the material package after the job was taken. Anyinformation from the material package record in the material databasemay be produced and attached to the material package. For example, eachtime a remaining amount of material is calculated, the value of theremaining amount of material may be printed on a label or tag andattached to the material package. Accordingly, a user may be able to seethe remaining about of material on the package. Once server 105 updatesthe material package record in stage 355, method 300 may then end atstage 360.

A mobile device (e.g., iPhone or Android) may be used to obtain dataregarding the material package. For example, the mobile device may beable to read beacon 220 wirelessly (e.g., via Bluetooth). As a result,the mobile deice may obtain information about the material and or thematerial package that may be stored in the memory on beacon 220including, for example, remaining length of material on the materialpackage. Furthermore, the mobile device may be able to read beacon label225 for the beacon code, transmit the beacon code to server 105, andreceive information about the material and or the material package thatmay be stored on server 105 including, for example, remaining length ofmaterial on the material package.

Consistent with embodiments of the disclosure, a device may be placed onthe material to detect the remaining amount of material in the materialpackage without having to weigh the material package. For example, thedevice may be placed at the tail end of the product comprising, forexample, a wire or cable. The device may “ping” the product with asignal to detect the length of the product based on the time that areflected wave returns. The device may detect the remaining length usingother processes and is not limited to the aforementioned process. Thedetected remaining length may be wirelessly reported, for example, tointerface 135 upon return of the material package to operations area120. The aforementioned length detecting device may be incorporated intoand with beacon 220. In other words, the aforementioned length detectingdevice and beacon 220 may comprise one device.

Embodiments of the disclosure may provide a very granular look into thematerial under the control of a particular operator (e.g., a utilitycompany). For example, the operator may control a plurality ofoperations areas of which operations area 120 may comprise one.Consistent with embodiments of the disclosure, the material database onserver 105 may allow the operator to know the amount and type ofmaterial on every material package in every operations area controlledby the operator. For example, the operator may control a number ofmaterial packages comprising coils of 2/0 triplex service drop cable.The operator may query the material database on server 105 and learn ata particular moment in time that: i) the operator has 3,435 coils of 2/0triplex service drop cable; ii) which operations center each coil is in;and iii) the total footage of 2/0 triplex service drop cable controlledby the operator is 515,250 feet.

Furthermore, this date may be augmented between operators in regions ofa county or even on a national basis. Extending the aforementionedexample, material database on server 105 may be queried to determine ona regional or national level: i) the number of coils of 2/0 triplexservice drop cable; ii) which operations center each coil is in; andiii) the total footage of 2/0 triplex service drop cable on a regionalor national level. This granularity of data may be useful tomanufactures when determining how to determine what types of materialsto manufacture. In other words, if there is a glut of 2/0 triplexservice drop cable, the manufacturer may decide not to make any more fora while. Also, during a national disaster such as a hurricane, it may beuseful to know where needed materials are to aid in restoration efforts.

FIG. 4 is a flow chart setting forth the general stages involved in amethod 400 consistent with an embodiment of the disclosure for providingmoisture content of a material package. Method 400 may be implementedusing a server 105 as described in more detail below with respect toFIG. 1. Ways to implement the stages of method 400 will be described ingreater detail below.

Method 400 may use weather data for the operations area and provide thisweather data to server 105. This weather data may be obtained from asource such as the National Oceanic and Atmospheric Administration(NOAA) or any other source that may maintain weather data thatcorresponds to the operations area. A weather device may be maintainedat, near, or within the operations area. The weather device may takeweather readings in order to provide the weather data to server 105.

Method 400 may begin at starting block 405 and proceed to stage 410where server 105 may determine a first date that may be the last date ofa most recent dry weather period. The first date may have an associatedmoisture content value comprising a dry weather period moisture contentvalue. For example, a dry weather period may comprise a period of time(e.g., between 2 and 5 days inclusively) in which it did not rain in thearea including the operations area. Within this period of time otherparameter may be present in order to consider the period of time dry,for example, the temperature may have been between certain temperaturevalues (e.g., 70 and 90 degrees Fahrenheit) and the relative humiditymay have been between certain relative humidity values (e.g., 0% and50%). Consistent with embodiments of the disclosure, the dry weatherperiod moisture content value may comprise a baseline moisture contentvalue that may be the equilibrium humidity value for the area includingthe operations during the dry weather period.

From stage 410, where server 105 determines the first date, method 400may advance to stage 415 where server 105 may determine a second datethat may comprise the last date in a most recent wet weather period. Thesecond date may have an associated moisture content value comprising awet weather period moisture content value. For example, a wet weatherperiod may comprise a period of time (e.g., between 2 and 5 daysinclusively) in which it rained each day in the area including theoperations area in an amount greater than or equal to a rain threshold(e.g., 0.2 inches to 1.0 inches). Consistent with embodiments of thedisclosure, at the end of the wet weather period, the material packagemay be considered saturated resulting in the wet weather period moisturecontent value being a saturation value (e.g., between 20% and 50%).

Once server 105 determines the second date in stage 415, method 400 maycontinue to stage 420 where server 105 may determine a third date thatmay be the last date the material package was weighed. The third datemay have an associated moisture content value comprising a determinedmoisture content value for the material package on the last date thematerial package was weighed. For example, as described above, thematerial package may enter and leave the operations area as it is usedfor jobs. Each time it reenters the operations area, the materialpackage may be weighed and a moisture content value may be obtained forthe material package at the time of weighing. The third date maycomprise the last day on which the material package was weighed.Accordingly, the associated moisture content value may comprise thedetermined moisture content value for the material package on the lastdate the material package was weighed. If the material package is new,it may have never been used and may not have been previously weighed atthe operations area. In this case, the third date may be the date thematerial package arrived at the operations area from the manufacturer.The associated moisture content value associated with the third date inthis case may comprise a value determined by the manufacturer that mayalready be in the material package record or may be given a defaultvalue.

After server 105 determines the third date in stage 420, method 400 mayproceed to stage 425 where server 105 may set a seed date equal to amost recent date of the first date, the second date, and the third date.For example, if the most recent dry weather period preceded the mostrecent wet weather period, then the seed date may comprise the seconddate (e.g., the last date of the wet weather period.) If the most recentdry weather period and the most recent wet weather period preceded thedate of the last time the material package was weighed, then the seeddate may be the last date the material package was weighed for example.

From stage 425, where server 105 sets the seed date, method 400 mayadvance to stage 430 where server 105 may set a seed moisture contentvalue equal to the associated moisture content value corresponding tothe most recent date of the first date, the second date, and the thirddate. For example, if the seed date is the first date, then the seedmoisture content value may be set at the above determined dry weatherperiod moisture content value. If the seed date is the second date, thenthe seed moisture content value may be set at the above determined wetweather period moisture content value. And if the seed date is the thirddate, then the seed moisture content value may be set at the moisturecontent value for the material package on the last date the materialpackage was weighed as obtained, for example, from the material packagerecord in the material package database.

Once server 105 sets the seed moisture content value in stage 430,method 400 may continue to stage 435 where server 105 may adjust theseed moisture content value. For example, server 105 may iteratethrough, and for each day after the seed date and up to and including acurrent date, server 105 may check the weather data to determine ifthere was precipitation on each corresponding day. Server 105 may thendecrease the seed moisture content value by a first predetermined amountfor each day that did not have precipitation. Furthermore, server 105may increase the seed moisture content value by a second predeterminedamount for each day that had precipitation between the seed date and upto an including the current date.

After server 105 adjusts the seed moisture content value in stage 435,method 400 may proceed to stage 440 where server 105 may set themoisture content of the material package equal to the adjusted seedmoisture content value. Once server 105 sets the moisture content of thematerial package equal to the adjusted seed moisture content value instage 440, method 400 may then end at stage 445.

Consistent with embodiments of the disclosure, the aforementionedweather data may be considered, for example, when: i) determining thedry weather period and the associated moisture content value comprisingthe dry weather period moisture content value; and ii) the wet weatherperiod and the associated moisture content value comprising the wetweather period moisture content value. Furthermore, the aforementionedweather data may be considered, for example, when adjusting the seedmoisture content value. Many variables in the weather data may influencethe moisture content of the material package. Any one or more of thesevariables may be obtained from the weather data and may be used, forexample, to increment and decrement the moisture content value of thematerial package. These variables may influence the moisture content ofthe material package for a given point in time. These variables maycomprise, but are not limited to, temperature for a given period,rainfall for a given period, relative humidity for a given period,average wind speed for a given period, and incident solar energy for agiven period (e.g., may vary if a day is cloudy or if a day is sunny).Any one or more of these variables may be used to calculate the moisturecontent for the material package, for example, at any given time. Windand solar may be used to calculate “radiation heat transfer” or“convection heat transfer”. For example, “conduction” heat transfer maybe influenced by temperature. These types of heat transfers may affectmoisture gain or loss rates for the material package.

FIG. 5 shows computing device 500. As shown in FIG. 5, computing device500 may include a processing unit 510 and a memory unit 515. Memory unit515 may include a software module 520 and a database 525. Whileexecuting on processing unit 510, software module 520 may performprocesses for determining a remaining amount of material in a materialpackage, including for example, any one or more of the stages frommethod 300 or method 400 described above with respect to FIG. 3 and FIG.4 or any one or more of the stages from method 600 described below withrespect to FIG. 6. Computing device 500, for example, may provide anoperating environment for any one or more of server 105, staging device125, and operations device 130. Server 105, staging device 125, andoperations device 130 may operate in other environments and is notlimited to computing device 500.

Computing device 500 may be implemented using a Wi-Fi access point, acellular base station, a tablet device, a mobile device, a smart phone,a telephone, a remote control device, a set-top box, a digital videorecorder, a handheld scanner, a cable modem, a personal computer, anetwork computer, a mainframe, a router, or other similarmicrocomputer-based device. Computing device 500 may comprise anycomputer operating environment, such as hand-held devices,multiprocessor systems, microprocessor-based or programmable senderelectronic devices, minicomputers, mainframe computers, and the like.Computing device 500 may also be practiced in distributed computingenvironments where tasks are performed by remote processing devices.Furthermore, computing device 500 may comprise, for example, a mobileterminal, such as a smart phone, a cellular telephone, a cellulartelephone utilizing Wireless Application Protocol (WAP) or unlicensedmobile access (UMA), personal digital assistant (PDA), intelligentpager, portable computer, a hand held computer, a conventionaltelephone, or a Wireless Fidelity (Wi-Fi) access point. Theaforementioned systems and devices are examples and computing device 500may comprise other systems or devices.

FIG. 6 is a flow chart setting forth the general stages involved in amethod 600 consistent with an embodiment of the invention fordetermining a remaining amount of material in a material package. Method600 may be implemented using, for example, server 105, staging device125, and operations device 130, each of which may be embodied incomputing device 500 as described in more detail above with respect toFIG. 5. Ways to implement the stages of method 600 will be described ingreater detail below.

Advantages of the process disclosed in FIG. 6 may include, but notlimited to, the automatic reporting of the material package's locationand the automatic determination of the material package's use based uponthe material package's periodic self-reported location. In addition, theremaining material on the material package may be updated based on thematerial package's weigh and moisture content subsequent to the materialpackage's automatically detected use. This process may utilize a beaconembedded or otherwise attached to the material package. The beacon maycomprise a device, for example, capable of communicating with server 105and other devices over a Long Term Evolution Cat-M1 (LTE-M) Network forInternet of Things. The beacon may communicate with server 105 in anyway and is not limited to communicating through interface 135 andoperations device 130.

Method 600 may begin at starting block 605 and proceed to stage 610where server 105 may receive a material package code corresponding to amaterial package comprising material. For example, the operation ofstage 610 may be similar to the operation of stage 310 as describedabove with respect to method 300.

From stage 610, where server 105 receives the material package codecorresponding to the material package comprising material, method 600may advance to stage 615 where server 105 may receive a beacon codecorresponding to a beacon associated with the material package. Forexample, the operation of stage 615 may be similar to the operation ofstage 315 as described above with respect to method 300.

Once server 105 receives the beacon code corresponding to the beaconassociated with the material package in stage 615, method 600 maycontinue to stage 620 where server 105 may record the beacon code in amaterial package record corresponding to the received material packagecode. For example, the operation of stage 620 may be similar to theoperation of stage 320 as described above with respect to method 300.

After server 105 records the beacon code in the material package recordcorresponding to the received material package code in stage 620, method600 may proceed to stage 630 where server 105 may determine that thematerial package has been used (e.g., has been used on a job). Indetermining that the material package has been used, server 105 maydetermine that the material package has moved from a previously recordedlocation (e.g., i) egressed from operations area 120 or ii) egressedfrom operations area 120 and has ingresses back into operations area120) based upon location data corresponding to the material package andthe beacon code. Server 105 may determine that the material package hasbeen used based just on the material package moving from a previouslyrecorded location (e.g., egressing from operations area 120). Thelocation data corresponding to the material package and the beacon codemay be periodically reported by the beacon located proximate to thematerial package. The beacon may comprise a device, for example, capableof communicating with server 105 over an LTE-M Network for Internet ofThings.

For example, the beacon may be embedded or otherwise attached to thematerial package. The beacon may periodically report its location toserver 105. When the material package comprising the beacon isstationary for a period of time, the beacon may report its location lessfrequently (e.g., stationary frequency). However, when the materialpackage comprising the beacon moves, the beacon may be triggered toreport its location more frequently (e.g., movement frequency). In otherwords, the movement frequency may be more frequent than the stationaryfrequency. This may be done in order to, for example, to conserve energy(e.g., battery life of the beacon). Material package movement mayindicate that the material package comprising the beacon is beingprepared for use on the job and therefore should report its locationmore frequently because it may be in transit. If the material packagehas not moved for a while, this may indicate that it is in storage andits location may be reported less frequently because it may bestationary. For instance, after the material package comprising thebeacon is stationary for one day; the beacon may report its locationdaily. However, when the beacon senses movement of the material package,the beacon may be triggered to report its location hourly. Thestationary frequency and the movement frequency may comprise other timeperiods and are not limited to daily and hourly. In order to detect thematerial package's movement, the beacon may be equipped with anaccelerometer.

In addition to detecting and reporting the material package's location,the beacon may sense the orientation of the material package. Forexample, it may be important to keep some material packages inapproximately a predetermined orientation. In other words, rotating somewire reels (e.g., rotating 90 degrees) may be damaging to the material(e.g., wire) on the reel. Accordingly, the beacon may periodicallydetect and report to server 105 the orientation or change in orientationof the material package.

In addition, to detecting its movement, the beacon may also be equippedto determine or otherwise detect its location. For example, the beaconmay include a Global Positioning System (GPS) receiver and mayaccordingly utilize the GPS to determine its location. Furthermore, thebeacon may include components that give it the ability to communicatewith and over cellular telephone systems. Accordingly, the beacon maydetermine or otherwise detect its location from using a cellulartelephone system, for example, through triangulation with a plurality ofcellular telephone facilities (e.g., cellular telephone towers). Inaddition, the beacon may include components that give it the ability toconnect wirelessly to a Wide Area Network (WAN) gateway or wirelessly toa Local Area Network (LAN) gateway, for example, via Wireless Fidelity(Wi-Fi) or Bluetooth. The gateway may be able to provide the beacon witha location of the gateway and the beacon may be able to use thisprovided location as an approximation of its location.

Furthermore, a crew may load the material package having the beacon on avehicle and drive the vehicle from operations area 120 in order to goand perform the job. The vehicle may be equipped with the ability todetermine the vehicle's location. The beacon on the material package mayinclude components that give it the ability to communicate with thevehicle and determine the vehicle's location. The beacon may be able touse the vehicle's location received from the vehicle as an approximationof the material package's location. Furthermore, a member of thevehicle's crew may have a device such as a tablet device, a mobiledevice, a smart phone, a personal computer, or other similarmicrocomputer-based device. The crew member's device may be able tolocate the crew member's device's location. The beacon on the materialpackage may include components that give it the ability to communicatewith the crew member's device and determine the crew member's device'slocation. The beacon may be able to use the crew member's device'slocation received from the crew member's device as an approximation ofthe material package's location.

From stage 630, where server 105 determines that the material packagehas been used (e.g., on the job), method 600 may advance to stage 640where server 105 may receive a weight of the material package that hasbeen used subsequent to the material package being used. For example,because the material package may have been used on the job, a portion ofthe material may have been removed from the material package. Becausethe portion of the material may have been removed from the materialpackage, it is desirable to know how much material remains on thematerial package. In order to determine how much material remains on thematerial package, a weight of the material package subsequent to thematerial package being used on the job may be obtained and used tocalculate the remaining material on the material package as describedbelow.

The weight of the material package used on the job may be obtained inany way. For example, upon ingress of the material package used on thejob back into operations area 120, the material package may be placed ina holding area for weighing. Once the material package has been weighed,the weight may be reported to operations device 130 that may in turnreport the weight of the material package to server 105. Consistent withembodiments of the disclosure, the vehicle used to perform the job mayhave a device to weigh the material package subsequent to the materialpackage being used on the job and report the weight of the materialpackage back to server 105.

In addition to the weight of the material package, the moisture contentof the material package that has been used on the job subsequent to thematerial package being used on the job may also be obtained and reportedto server 105. For example, when the material package comprises a reel(e.g., a wooden reel), a moisture device (e.g., a moisture meter) may beused to obtain the moisture content of the reel. As stated above, themoisture meter may comprise, but is not limited to, an L600 SeriesDigital Recording Handheld Moisture Meter provided by Wagner Meters of326 Pine Grove Road, Rogue River, Oreg. 97537.

The moisture content of the reel may comprise a percent moisture value.Because the amount of moisture in the material package may fluctuateover time, the weight of the material package may not only change due tomaterial being removed, but the weight of the material package may alsochange due to moisture being added or taken away from the materialpackage. The moisture device may read the percentage of moisture in thematerial package (e.g., reel). One moisture percentage reading may betaken or several moisture percentage readings may be taken at differentlocation on the material package and averaged. Consistent withembodiments of the disclosure, the vehicle used to perform the job mayhave a device to read the moisture content of the material packagesubsequent to the material package being used on the job and report themoisture content to server 105.

Consistent with other embodiments of the disclosure, the moisturecontent value may be obtained in other ways. For example, a samplematerial (e.g., wood) being the same or similar to the material that thematerial package is made of may be kept in the same environment as thematerial packages in operations area 120. Rather than taking a moisturepercentage reading from each material package, the moisture percentagereading of the sample may be used. Furthermore, historic moisturecontent values for material (e.g., wood) being the same or similar tothe material that the material package is made of may be kept foroperations area 120's environment. Rather than taking a moisturepercentage reading of each material package, the moisture percentagehistoric values may be used instead. The historic values may be afunction of weather and season for example. Furthermore, the moisturecontent value may be obtained by method 400 described above. Once theweight and the moisture content values are obtained, the materialpackage may be placed in the general warehouse of operations area 120for use on yet another job.

Consistent with embodiments of the disclosure, equipment (e.g., a forktruck) used to remove the material package from the vehicle for thereturn of the material package back into operations area 120 may have adevice to weigh and read the moisture content of the material packageand wirelessly report the weight and moisture content to interface 135.Consistent with other embodiments of the disclosure, the materialpackage itself may include a device to weigh itself and report thisweight back to server 105 through, for example, the beacon or throughinterface 135. Furthermore, the material package itself may include adevice to obtain its own moisture content and report this reading backto server 105 through, for example, the beacon or through interface 135.

Once server 105 receives the weight of the material package that hasbeen used (e.g., on the job) subsequent to the material package beingused in stage 640, method 600 may continue to stage 645 where server 105may query, based upon the beacon code and in response to receiving theweight of the material package, the material database for a materialpackage record. For example, server 105 may query the material databasefor the material package record to obtain the per unit weight of thematerial on the material package, the previous weight of the materialpackage before the job, and the moisture content of the material packagewhen the previous weight was taken of the material package before thejob.

After server 105 queries, based upon the beacon code and in response toreceiving the weight of the material package, the material database fora material package record in stage 645, method 600 may proceed to stage650 where server 105 may calculate a remaining amount of materialcorresponding to the material package based upon the received weight andother data from the material package record found from the materialdatabase query. For example, the operation of stage 650 may be similarto the operation of stage 350 as described above with respect to method300.

From stage 650, where server 105 calculates the remaining amount ofmaterial corresponding to the material package based upon the receivedweight and other data from the material package record found from thematerial database query, method 600 may advance to stage 655 whereserver 105 may update the material package record in the materialdatabase with the calculated remaining amount of material correspondingto the material package. For example, the operation of stage 655 may besimilar to the operation of stage 355 as described above with respect tomethod 300. Once server 105 updates the material package record in thematerial database with the calculated remaining amount of materialcorresponding to the material package in stage 655, method 600 may thenend at stage 660.

Embodiments of the disclosure, for example, may be implemented as acomputer process (method), a computing system, or as an article ofmanufacture, such as a computer program product or computer readablemedia. The computer program product may be a computer storage mediareadable by a computer system and encoding a computer program ofinstructions for executing a computer process. The computer programproduct may also be a propagated signal on a carrier readable by acomputing system and encoding a computer program of instructions forexecuting a computer process. Accordingly, the present disclosure may beembodied in hardware and/or in software (including firmware, residentsoftware, micro-code, etc.). In other words, embodiments of the presentdisclosure may take the form of a computer program product on acomputer-usable or computer-readable storage medium havingcomputer-usable or computer-readable program code embodied in the mediumfor use by or in connection with an instruction execution system. Acomputer-usable or computer-readable medium may be any medium that cancontain, store, communicate, propagate, or transport the program for useby or in connection with the instruction execution system, apparatus, ordevice.

The computer-usable or computer-readable medium may be, for example butnot limited to, an electronic, magnetic, optical, electromagnetic,infrared, or semiconductor system, apparatus, device, or propagationmedium. More specific computer-readable medium examples (anon-exhaustive list), the computer-readable medium may include thefollowing: an electrical connection having one or more wires, a portablecomputer diskette, a random access memory (RAM), a read-only memory(ROM), an erasable programmable read-only memory (EPROM or Flashmemory), an optical fiber, and a portable compact disc read-only memory(CD-ROM). Note that the computer-usable or computer-readable mediumcould even be paper or another suitable medium upon which the program isprinted, as the program can be electronically captured, via, forinstance, optical scanning of the paper or other medium, then compiled,interpreted, or otherwise processed in a suitable manner, if necessary,and then stored in a computer memory.

While certain embodiments of the disclosure have been described, otherembodiments may exist. Furthermore, although embodiments of the presentdisclosure have been described as being associated with data stored inmemory and other storage mediums, data can also be stored on or readfrom other types of computer-readable media, such as secondary storagedevices, like hard disks, floppy disks, or a CD-ROM, a carrier wave fromthe Internet, or other forms of RAM or ROM. Moreover, the semantic dataconsistent with embodiments of the disclosure may be analyzed withoutbeing stored. In this case, in-line data mining techniques may be usedas data traffic passes through, for example, a caching server or networkrouter. Further, the disclosed methods' stages may be modified in anymanner, including by reordering stages and/or inserting or deletingstages, without departing from the disclosure.

Furthermore, embodiments of the disclosure may be practiced in anelectrical circuit comprising discrete electronic elements, packaged orintegrated electronic chips containing logic gates, a circuit utilizinga microprocessor, or on a single chip containing electronic elements ormicroprocessors. Embodiments of the disclosure may also be practicedusing other technologies capable of performing logical operations suchas, for example, AND, OR, and NOT, including but not limited tomechanical, optical, fluidic, and quantum technologies. In addition,embodiments of the disclosure may be practiced within a general purposecomputer or in any other circuits or systems.

Embodiments of the disclosure may be practiced via a system-on-a-chip(SOC) where each or many of the components illustrated in FIG. 2 may beintegrated onto a single integrated circuit. Such an SOC device mayinclude one or more processing units, graphics units, communicationsunits, system virtualization units and various application functionalityall of which may be integrated (or “burned”) onto the chip substrate asa single integrated circuit. When operating via an SOC, thefunctionality described herein with respect to embodiments of thedisclosure, may be performed via application-specific logic integratedwith other components of computing device 500 on the single integratedcircuit (chip).

Embodiments of the present disclosure, for example, are described abovewith reference to block diagrams and/or operational illustrations ofmethods, systems, and computer program products according to embodimentsof the disclosure. The functions/acts noted in the blocks may occur outof the order as shown in any flowchart. For example, two blocks shown insuccession may in fact be executed substantially concurrently or theblocks may sometimes be executed in the reverse order, depending uponthe functionality/acts involved.

While the specification includes examples, the disclosure's scope isindicated by the following claims. Furthermore, while the specificationhas been described in language specific to structural features and/ormethodological acts, the claims are not limited to the features or actsdescribed above. Rather, the specific features and acts described aboveare disclosed as example for embodiments of the disclosure.

What is claimed is:
 1. A method comprising: determining that a materialpackage has been used, wherein determining that the material package hasbeen used comprises determining that the material package has moved froma previously recorded location based upon location data corresponding tothe material package and a beacon code, the location data correspondingto the material package and the beacon code being periodically reportedby a beacon located proximate to the material package; receiving aweight of the material package that has been used subsequent to thematerial package being used; querying, based upon the beacon code and inresponse to receiving the weight of the material package, the materialdatabase for a material package record; calculating a remaining amountof material corresponding to the material package based upon thereceived weight and data from the material package record found from thematerial package record query; and updating the material package recordwith the calculated remaining amount of material corresponding to thematerial package.
 2. The method of claim 1, wherein determining that thematerial package has been used further comprises determining that thematerial package has ingressed back into an operations area.
 3. Themethod of claim 1, wherein determining that the material package hasbeen used comprises determining that the material package has been usedwherein the material package comprises a wooden wire reel.
 4. The methodof claim 1, wherein determining that the material package has been usedcomprises determining that the material package has been used whereinthe material package comprises a reel-less package.
 5. The method ofclaim 1, wherein determining that the material package has been usedcomprises determining that the material package has been used whereinthe material package comprises material comprising one of the following:electrical cable, electrical wire, and flexible conduit.
 6. The methodof claim 1, wherein determining that the material package has been usedcomprises determining that the material package has been used whereinthe material package comprises material comprising a long continuousflexible material capable of being wound on a reel.
 7. The method ofclaim 1, further comprising saving the material package record in amemory in the beacon.
 8. The method of claim 1, wherein calculating theremaining amount of material corresponding to the material packagecomprises considering a moisture content of the material package.
 9. Themethod of claim 8, further comprising obtaining a moisture content valuecorresponding to the moisture content of the material package.
 10. Themethod of claim 9, wherein obtaining the moisture content valuecomprises using a moisture meter.
 11. The method of claim 1, furthercomprising: receiving a material package code corresponding to thematerial package; receiving the beacon code corresponding to the beaconassociated with the material package; recording the beacon code in thematerial package record corresponding to the received material packagecode, the material package record including the material package datacorresponding to the material, the material package record being in amaterial database; and updating location data in the material packagerecord when the material package enters the operations area for thefirst time.
 12. The method of claim 1, where querying for the materialpackage record comprises querying for the material package record in amaterial database.
 13. The method of claim 1, wherein calculating theremaining amount of material corresponding to the material packagecomprises considering and obtaining a moisture content of the materialpackage wherein obtaining the moisture content value comprises:determining a first date, the first date being the last date of a mostrecent dry weather period for the operations area and having anassociated moisture content value comprising a dry weather periodmoisture content value; determining a second date, the second date beingthe last date in a most recent wet weather period for the operationsarea and having the associated moisture content value comprising a wetweather period moisture content value; determining a third date, thethird date being the last date the material package was weighed andhaving the associated moisture content value comprising a determinedmoisture content value for the material package on the last date thematerial package was weighed; setting a seed date equal to a most recentdate of the first date, the second date, and the third date; setting aseed moisture content value equal to the associated moisture contentvalue corresponding to the most recent date of the first date, thesecond date, and the third date; adjusting the seed moisture contentvalue wherein adjusting the seed moisture content value comprises;decreasing the seed moisture content value by a first predeterminedamount for each day that had precipitation for the operations areabetween the seed date and a current date, and increasing the seedmoisture content value by a second predetermined amount for each daythat had precipitation between the seed date and the current date; andsetting the moisture content value of the material package equal to theadjusted seed moisture content value.
 14. A system comprising: a memorystorage; and a processing unit coupled to the memory storage, whereinthe processing unit is operative to: determine that a material packagehas been used on a job, wherein determining that the material packagehas been used on the job comprises determining that the material packagehas egressed from an operations area and has ingressed back into theoperations area based upon location data corresponding to the materialpackage and a beacon code, the location data corresponding to thematerial package and the beacon code being periodically reported by abeacon located proximate to the material package; receive a weight ofthe material package that has been used on the job subsequent to thematerial package being used on the job; query, based upon the beaconcode and in response to receiving the weight of the material package,the material database for a material package record; calculate aremaining amount of material corresponding to the material package basedupon the received weight and data from the material package record foundfrom the material package record query; and update the material packagerecord with the calculated remaining amount of material corresponding tothe material package.
 15. The system of claim 14, wherein the processingunit being operative to calculate the remaining amount of materialcorresponding to the material package comprises the processing unitbeing operative to consider a moisture content of the material package.16. The system of claim 15, further comprising the processing unit beingoperative to obtain a moisture content value corresponding to themoisture content of the material package.
 17. The system of claim 14,wherein the processing unit being operative to calculate the remainingamount of material corresponding to the material package comprises theprocessing unit being operative to consider and obtain a moisturecontent of the material package wherein the processing unit beingoperative to obtain the moisture content value comprises the processingunit being operative to: determine a first date, the first date beingthe last date of a most recent dry weather period for the operationsarea and having an associated moisture content value comprising a dryweather period moisture content value; determine a second date, thesecond date being the last date in a most recent wet weather period forthe operations area and having the associated moisture content valuecomprising a wet weather period moisture content value; determine athird date, the third date being the last date the material package wasweighed and having the associated moisture content value comprising adetermined moisture content value for the material package on the lastdate the material package was weighed; set a seed date equal to a mostrecent date of the first date, the second date, and the third date; seta seed moisture content value equal to the associated moisture contentvalue corresponding to the most recent date of the first date, thesecond date, and the third date; adjust the seed moisture content valuewherein the processing unit being operative to adjust the seed moisturecontent value comprises the processing unit being operative to; decreasethe seed moisture content value by a first predetermined amount for eachday that had precipitation for the operations area between the seed dateand a current date, and increase the seed moisture content value by asecond predetermined amount for each day that had precipitation betweenthe seed date and the current date; and set the moisture content valueof the material package equal to the adjusted seed moisture contentvalue.
 18. A computer-readable medium that stores a set of instructionswhich when executed perform a method comprising: determining that amaterial package has been used on a job, wherein determining that thematerial package has been used on the job comprises determining that thematerial package has egressed from an operations area and has ingressedback into the operations area based upon location data corresponding tothe material package and a beacon code, the location data correspondingto the material package and the beacon code being periodically reportedby a beacon located proximate to the material package; receiving aweight of the material package that has been used on the job subsequentto the material package being used on the job; querying, based upon thebeacon code and in response to receiving the weight of the materialpackage, the material database for a material package record;calculating a remaining amount of material corresponding to the materialpackage based upon the received weight and data from the materialpackage record found from the material package record query; andupdating the material package record with the calculated remainingamount of material corresponding to the material package.
 19. Thecomputer-readable medium of claim 18, wherein calculating the remainingamount of material corresponding to the material package comprisesconsidering a moisture content of the material package.
 20. Thecomputer-readable medium of claim 18, further comprising: receiving amaterial package code corresponding to the material package; receivingthe beacon code corresponding to the beacon associated with the materialpackage; recording the beacon code in the material package recordcorresponding to the received material package code, the materialpackage record including the material package data corresponding to thematerial, the material package record being in a material database; andupdating location data in the material package record when the materialpackage enters the operations area for the first time.